JPH04141223A - Tank container - Google Patents

Abstract

PURPOSE:To reduce the assembling work in a container main body to a large extent and to efficiently prepare the container main body by assembling a flow path wall outside the container main body and inserting the flow path wall in the container main body to fix the same to the inner surface thereof in a close contact state. CONSTITUTION:Partition walls 7 are parallelly provided in the direction right- angled to the rear of an inner plate so as to leave intervals therebetween and outer strips 8 are provided between the outer ends of the partition walls 7 and a flow path wall 5A having flow paths of a heating or cooling medium partitioned by the partition plates 7 is formed between the inner plate 6 and the outer strips 8. This flow path wall 5A is fixed to the inner wall of a container main body 1 in a close contact state by the outer strips 8. As a result, the assembling work in the container main body is reduced to a large extent and finishing work is set to the usual finishing work in a container to make it possible to efficiently prepare the container and maintenance work is also almost set to the usual maintenance work in the container.

Description

【発明の詳細な説明】 ［産業上の利用分野］ この発明は、化学・薬品・食品工業等で反応槽、撹拌槽
として使用される容器（以下、槽容器という。）に関す
るものである。[Detailed Description of the Invention] [Industrial Application Field] The present invention relates to a container (hereinafter referred to as a tank container) used as a reaction tank or stirring tank in the chemical, pharmaceutical, food industries, etc.

〔従来の技術〕[Conventional technology]

一般に、この種の槽容器は、容器本体を円筒形胴部の両
端に皿形鏡面板を溶接した耐圧密閉容器で形成すると共
に、この容器本体に、内部発生熱を除去するための除熱
機構を設けている。Generally, this type of tank container is formed of a pressure-resistant sealed container with a cylindrical body and dish-shaped mirror plates welded to both ends of the container body, and a heat removal mechanism is installed in the container body to remove internally generated heat. has been established.

従来、槽容器の除熱機構としては、第４図に示すように
容器本体１の外部にジャケット１５を付設したジャケッ
ト方式ａ、第５図に示すように容器本体１の内面より内
側に螺旋状のパイプ１６を固定配置した内部パイプ方式
す又は第６図に示すように容器本体１の内面より内側に
容器本体長手方向に延在し、かつ端部がエルボ接続され
たパイプ１７を容器本体周方向に蛇行するように固定し
て配置した内部パイプ方式Ｃ１第７図に示すように容器
本体工の内面と直角に仕切板１８を間隔をおいて並設し
、仕切板工８の先端間に内ストリップ１９を跨設し、内
ストリンプ１９と前記容器本体１の内面との間に仕切板
■８により仕切られた螺旋状の流路２０を形成したイン
ナージャケット方式ｄ（特開昭５７−１４７５０２号公
報参照）等が知られている。Conventionally, as a heat removal mechanism for a tank container, there is a jacket method a in which a jacket 15 is attached to the outside of the container body 1 as shown in FIG. Alternatively, as shown in FIG. 6, a pipe 17 extending inside the inner surface of the container body 1 in the longitudinal direction of the container body and having an elbow-connected end is installed around the container body. Internal pipe system C1 fixedly arranged so as to meander in the direction As shown in FIG. Inner jacket method d (Japanese Patent Application Laid-Open No. 57-147502 (see Publication No. 2003), etc. are known.

〔発明が解決しようとする課題〕[Problem to be solved by the invention]

容器本体壁を通して熱交換するジャケット方式ａは、壁
厚が厚いと容器本体壁を通しての熱伝達率が低下するた
め不利となる。また、容器を大型化する場合、強度面か
ら容器本体壁を厚くしなければならないから、この方式
では容器の大型化に対応し難いという不都合があった。Jacket method a, in which heat is exchanged through the wall of the container body, is disadvantageous because the heat transfer coefficient through the wall of the container body decreases if the wall thickness is thick. Furthermore, when increasing the size of the container, the wall of the container main body must be made thicker from the viewpoint of strength, so this system has the disadvantage that it is difficult to cope with the increase in the size of the container.

容器本体１の内側でパイプ１６．１７の壁を通して熱交
換する内部パイプ方式す、ｃは、パイプ径でパイプの肉
厚が決まり、容器本体ｌの内径に比べてパイプ径が小さ
いため、パイプの肉厚が薄くなっており、熱伝達性が優
れているという利点を有する反面、パイプ自体及びパイ
プ固定用のサポートに内容物が付着して熱伝達を阻害し
、また付着物が剥離して製品中に混入するから、運転効
率が不安定になると共に、製品の劣化が生しるという不
都合があった。In internal pipe method (c), which exchanges heat through the walls of pipes 16 and 17 inside the container body 1, the wall thickness of the pipe is determined by the pipe diameter, and the pipe diameter is smaller than the inner diameter of the container body l. Although the wall thickness is thinner and has the advantage of excellent heat transfer properties, the contents may adhere to the pipe itself and the support for fixing the pipe, impeding heat transfer, and the adhesion may peel off, causing damage to the product. As a result, the operating efficiency becomes unstable and the product deteriorates.

更に、容器本体１の内側で内ストリップ１９を通して熱
交換するインナージャケット方式ｄは、前記方式ａ、ｂ
、ｃの不都合を解消し得ると共に、仕切板１８の間隔て
内ストリップ１９の肉厚が決まり、容器本体１の内径に
比べて仕切板１８の間隔が小さいため、内ストリップ１
９の肉厚は薄くなり、熱伝達性が優れているという利点
を有する反面、容器本体１の内面に仕切板Ｉ８を間隔を
おいて容器本体１の内面に一本一本取り付けた後、仕切
Ｆｉ１８の先端間に内ストリップ１９を跨設するから、
現場作業で手間のかかる組立てが必要になると同時に、
多数存在する内ストリップ１９間の溶接部が表面に露出
するから、表面を平滑に仕上げる必要があり、製作が面
倒で手間がかかる。Furthermore, the inner jacket method d, which exchanges heat through the inner strip 19 inside the container body 1, is different from the above methods a and b.
, c can be solved, and the thickness of the inner strip 19 is determined by the interval between the partition plates 18, and since the interval between the partition plates 18 is smaller than the inner diameter of the container body 1, the inner strip 1
9 has the advantage of being thinner and having better heat transfer properties.However, after attaching the partition plates I8 one by one to the inner surface of the container body 1 at intervals, Since the inner strip 19 is installed between the tips of the Fi 18,
At the same time, time-consuming assembly is required on-site,
Since the welded portions between the many inner strips 19 are exposed on the surface, it is necessary to finish the surface smooth, making manufacturing difficult and time-consuming.

また、溶接部が腐食性液に接する場合、腐食の如何を確
認し必要に応じて補修する必要があり、頻繁なメンテナ
ンス作業が必要になる出いう不都合があった。Further, when the welded portion comes into contact with a corrosive liquid, it is necessary to check for corrosion and repair as necessary, resulting in the inconvenience of requiring frequent maintenance work.

〔発明の目的〕[Purpose of the invention]

この発明は前記インナージャケット方式の課題を解決す
るためになしたもので、容器本体内での組立て作業を大
幅に少なくし、かつ仕上げ作業を通常の容器内仕上げ作
業程度にして能率良く製作できるようにすると共に、メ
ンテナンス作業も通常の容器内メンテナンス作業程度で
済む槽容器を提供することを目的とする。This invention was made in order to solve the problems of the inner jacket method, and allows for efficient production by significantly reducing the assembly work inside the container body and reducing the finishing work to the level of normal finishing work inside the container. It is an object of the present invention to provide a tank container in which maintenance work can be carried out at the same level as normal maintenance work inside the container.

〔課題を解決するための手段〕[Means to solve the problem]

この発明に係る槽容器は、第１図〜第３図に示すように
、内板６の裏面と直角に仕切板７を間隔をおいて並設し
、仕切板７の先端間に外ストリップ８を跨設し、前記内
板６と外ストリップ８との間に仕切板７により仕切られ
た熱媒又は冷媒の流路９（９２，９□）を有する流路壁
５Ａ　（５Ｂ）を形成し、二〇流路壁５Ａ　（５Ｂ）を
外ストリップ８にて容器本体ｌの内面、即ち、被熱交換
材と接触する容器本体１の胴部２及び底部鏡面板３部の
内面に密着させて固定したことを特徴としており、かか
る構成によって前記目的を達成するものである。As shown in FIGS. 1 to 3, the tank container according to the present invention has partition plates 7 arranged in parallel at right angles to the back surface of the inner plate 6 at intervals, and an outer strip 8 between the tips of the partition plates 7. A channel wall 5A (5B) is formed between the inner plate 6 and the outer strip 8 and having a heat medium or coolant flow channel 9 (92, 9□) partitioned by a partition plate 7. , 20. The flow path wall 5A (5B) is brought into close contact with the inner surface of the container body 1 using the outer strip 8, that is, the inner surface of the body 2 and the bottom mirror plate 3 of the container body 1 that are in contact with the material to be heat exchanged. It is characterized in that it is fixed, and this configuration achieves the above object.

（作　用） 製作時、流路壁５Ａ　（５Ｂ）を容器本体ｌの内面に密
着させて固定するだけで済むと共に、その表面は平滑で
溶接部等が露出しない内板６で構成されており、はとん
ど仕上げを必要としない。(Function) During manufacture, it is sufficient to simply fix the channel wall 5A (5B) in close contact with the inner surface of the container body l, and the inner plate 6 has a smooth surface and does not expose welded parts. , requires little finishing.

使用時、容器本体ｌ内の処理液は、流路壁５Ａ（５Ｂ）
の内板６を通して流路９　（９，，９□）内を流れる熱
媒又は冷媒と熱交換するが、仕切板７０間隔で内板６の
肉厚が決まり、容器本体１の内径に比べて仕切板７の間
隔は小さいため、内板６の肉厚は薄くなり、伝熱抵抗が
小さく、熱伝達性に優れているから、前記内板６を通し
ての熱媒又は冷媒との熱交換が効率良く行われることに
なる。During use, the processing liquid inside the container body l flows through the channel wall 5A (5B).
The inner plate 6 exchanges heat with the heat medium or refrigerant flowing in the flow path 9 (9, 9□), but the thickness of the inner plate 6 is determined by the interval between the partition plates 70, and is Since the distance between the partition plates 7 is small, the inner plate 6 has a thin wall thickness, has low heat transfer resistance, and has excellent heat transfer properties, so that heat exchange with the heating medium or refrigerant through the inner plate 6 is efficient. It will be well done.

〔実　施　例］ 以下、この発明の一実施例を第１図及び第２図に沿って
説明する。[Embodiment] An embodiment of the present invention will be described below with reference to FIGS. 1 and 2.

第１図は螺旋状の流路を内面に設けた槽容器、第２図は
その要部拡大断面を示している。FIG. 1 shows a tank container having a spiral flow path on its inner surface, and FIG. 2 shows an enlarged cross-section of the main part thereof.

図中１は容器本体で、円筒形胴部２の上下両端に皿形鏡
面板３．４を溶接した耐圧密閉容器となっている。In the figure, reference numeral 1 denotes a container body, which is a pressure-resistant sealed container in which dish-shaped mirror plates 3.4 are welded to both upper and lower ends of a cylindrical body 2.

５Ａは流路壁で、隅肉溶接で内板６の裏面と直角に仕切
板７を間隔をおいて並設し、突合せ溶接で仕切板７の先
端間に外ストリップ８を跨設し、前記内板６と外ストリ
ップ８との間に仕切板７により仕切られた熱媒又は冷媒
の流路９を螺旋状に設けている。Reference numeral 5A denotes a channel wall, in which partition plates 7 are arranged in parallel at intervals at right angles to the back surface of the inner plate 6 by fillet welding, and an outer strip 8 is placed across between the tips of the partition plates 7 by butt welding. A heat medium or coolant flow path 9 partitioned by a partition plate 7 is provided in a spiral shape between the inner plate 6 and the outer strip 8.

流路壁５Ａは容器本体１の外部で予め製作されており、
次のように容器本体１の内部に配置され、外ストリップ
８にて容器本体１の内面に密着させて固定されると共に
、流路９の入口１０及び出口１１が夫々容器本体１の底
部及び上部に外方に突出させて設けられている。The channel wall 5A is manufactured in advance outside the container body 1,
It is arranged inside the container body 1 as follows, and is tightly fixed to the inner surface of the container body 1 by the outer strip 8, and the inlet 10 and outlet 11 of the flow path 9 are located at the bottom and top of the container body 1, respectively. It is provided so as to protrude outward.

即ち、流路壁５Ａは、底部鏡面板３を取り付けた円筒形
胴部２の内部に上部鏡面板４の取付は前に挿入された後
、外ストリップ８にて容器本体１の円筒形胴部２及び底
部鏡面板３部の内面に第２図に示すように隙間がほとん
どなく押し付けられた状態で固定される。次いで、流路
９の入口１０及び出口１１が設けられた後、円筒形胴部
２に上部鏡面板４が取り付けられている。That is, after the channel wall 5A is inserted into the cylindrical body 2 to which the bottom mirror plate 3 is attached before the upper mirror plate 4 is attached, the channel wall 5A is inserted into the cylindrical body of the container body 1 with the outer strip 8. 2 and the inner surfaces of the bottom mirror plate 3, as shown in FIG. 2, they are pressed and fixed with almost no gaps. Next, after the inlet 10 and outlet 11 of the flow path 9 are provided, the upper mirror plate 4 is attached to the cylindrical body 2.

流路壁５Ａの固定は、例えば流路壁５Ａに設けたラグの
止着により、或いは直接溶接（連続、断続のいかんを問
わない。）により、流路壁５Ａの上端を第１図のイに示
すように円筒形胴部２に連結し、かつ、流路壁５Ａの下
端を第１図の口に示すように槽容器ノズル１２のまわり
の底部鏡面板３部又は同図のハに示すように槽容器ノズ
ル１２に連結して行えば良い。尚、連続溶接によれば、
槽容器内部を耐蝕材で構成する場合、流路壁５の接液部
と容器本体１の接液部とを耐蝕材で構成し、その他の部
分は一般の鋼材で構成するだけで良い。The channel wall 5A can be fixed by fixing the upper end of the channel wall 5A to the channel wall 5A as shown in FIG. The lower end of the channel wall 5A is connected to the cylindrical body 2 as shown in FIG. This can be done by connecting it to the tank container nozzle 12 like this. Furthermore, according to continuous welding,
When the inside of the tank container is made of a corrosion-resistant material, it is only necessary to make the liquid-contacting part of the channel wall 5 and the liquid-contacting part of the container body 1 of the corrosion-resistant material, and to make the other parts of general steel.

尚、実施例では、螺旋状流路９を有する有底円筒状の流
路壁５Ａを容器本体１の内面に固定した例について説明
したが、第３図に示すように、流路壁５Ａと同一形状に
形成した螺旋状流路９．が下端部（皿状部分）に設けら
れ、その上部（円筒状部分）に容器本体周方向に蛇行し
た流路９□が設けられた流路壁５Ｂを容器本体ｌの外部
で予め製作し、この流路壁５Ｂを、上部鏡面板４の取付
は前、容器本体ｌの内部に挿入して外ストリップ８にて
底部鏡面板３部及び円筒形胴部２の内面に密着させて固
定すると共に、流路９Ｉの入口１０１及び出口１１．を
夫々底部鏡面板３部の下部及び上部に外方に突出させて
設け、かつ流路９□の入口１０ｇ及び出口１１□を夫々
円筒形胴部２の下部及び上部に外方に突出させて設けて
も良い。In the embodiment, an example was explained in which the bottomed cylindrical channel wall 5A having the spiral channel 9 was fixed to the inner surface of the container body 1, but as shown in FIG. Spiral channel 9 formed in the same shape. is provided at the lower end (dish-shaped part), and a flow passage wall 5B is provided in the upper part (cylindrical part) with a flow passage 9 □ that meanders in the circumferential direction of the container main body, and is prepared in advance outside the container main body l. Before attaching the upper mirror plate 4, this channel wall 5B is inserted into the container main body l and fixed in close contact with the bottom mirror plate 3 and the inner surface of the cylindrical body 2 using the outer strip 8. , the inlet 101 and the outlet 11. of the flow path 9I. are provided to protrude outward from the bottom and top of the bottom mirror plate 3, respectively, and the inlet 10g and outlet 11□ of the channel 9□ are made to protrude outward from the bottom and top of the cylindrical body 2, respectively. It may be provided.

前記流路壁５Ｂの上部（円筒状部分）は、内板６の裏面
と直角に仕切板７を間隔をおき容器本体長手方向に延在
させて並設し、仕切板７の先端間に外ストリップ８を跨
設し、かつ、容器本体長手方向の両端部に夫々閉塞板１
３（下部閉塞板１３は流路９．を形成する仕切板で兼用
可能）を取り付けると共に、仕切板７の端部に容器本体
周方向に互い違いとなるように切欠部１４を設け、前記
内板６と外ストリップ８との間に仕切板７により仕切ら
れ、かつ切欠部１４を流れの反転部とじた流路９□を設
けている。The upper part (cylindrical part) of the channel wall 5B has partition plates 7 arranged at right angles to the back surface of the inner plate 6 at intervals and extending in the longitudinal direction of the container body. Closing plates 1 are provided across the strip 8 and at both ends of the container body in the longitudinal direction.
3 (the lower closing plate 13 can also be used as a partition plate for forming the flow path 9), and cutouts 14 are provided at the ends of the partition plate 7 so as to be staggered in the circumferential direction of the container body. A flow path 9□ is provided between the outer strip 6 and the outer strip 8, which is partitioned by a partition plate 7 and has the notch 14 as a flow reversal portion.

また、前記流路壁５Ａ又は５Ｂの上部（円筒状部分）に
相当する図示しない円筒状の流路壁を前記と同様に円筒
形胴部２の内面に固定し、底部鏡面板３部には流路壁を
設けなくても良いことは言うまでもない。二〇流路壁で
は、内板６の下端と直角に下部閉塞板１３を一体に連設
したものを使用する。Further, a cylindrical channel wall (not shown) corresponding to the upper part (cylindrical portion) of the channel wall 5A or 5B is fixed to the inner surface of the cylindrical body 2 in the same manner as described above, and the bottom mirror plate 3 is fixed to the inner surface of the cylindrical body 2. Needless to say, it is not necessary to provide a channel wall. For the flow path wall 20, a lower closing plate 13 is integrally installed at right angles to the lower end of the inner plate 6.

以上の構成において、流路壁５Ａ（５Ｂ）は−体に組み
立てられているがら、流路壁５Ａ　（５Ｂ）を容器本体
１内に挿入し内面に密着させて固定した後、上部鏡面板
４を取り付けるだけで良い。In the above configuration, although the channel wall 5A (5B) is assembled into a body, after inserting the channel wall 5A (5B) into the container body 1 and fixing it in close contact with the inner surface, the upper mirror plate 4 Just attach it.

また、流路壁５Ａ　（５Ｂ）の表面は平滑で溶接部等が
露出しない内板６で構成されているから、はとんど仕上
げを必要としないと共に、使用時にも処理液の付着が少
なく、良好な処理が可能となる。In addition, since the surface of the channel wall 5A (5B) is smooth and consists of the inner plate 6 with no exposed welded parts, it hardly requires finishing, and there is less adhesion of processing liquid during use. , good processing is possible.

流路壁５Ａ　（５Ｂ）の流路９（９８，９□）に入口１
０（１０，、ｌＯ□）から供給された熱媒又は冷媒は、
流路９（９０，９□）内を容器本体ｌの内面に沿って流
れて出口１１（１１，，１１□）から流出する。従って
、槽容器を攪拌槽として使用する場合、容器本体１内で
攪拌される処理液は、流路壁５Ａ　（５Ｂ）の内板６を
通して流路９（９１，９ｔ）内を流れる熱媒又は冷媒と
熱交換することにより加熱叉と冷却されることになるが
、仕切板７の間隔で内板６の肉厚が決まり、容器本体ｌ
の内径に比べて仕切板７の間隔は小さいため、内板６の
肉厚は薄くなり、伝熱抵抗が小さく、熱伝達性に優れて
いるから、前記内板６を通しての熱媒又は冷媒との熱交
換が効率良く行われることになる。Inlet 1 to flow path 9 (98, 9□) of flow path wall 5A (5B)
The heating medium or refrigerant supplied from 0 (10,, lO□) is
It flows in the flow path 9 (90, 9□) along the inner surface of the container body l and flows out from the outlet 11 (11, 11□). Therefore, when the tank container is used as a stirring tank, the processing liquid stirred in the container main body 1 is a heat medium or Heating and cooling will occur by exchanging heat with the refrigerant, but the thickness of the inner plate 6 is determined by the interval between the partition plates 7, and the container body l
Since the distance between the partition plates 7 is small compared to the inner diameter of the inner plate 6, the wall thickness of the inner plate 6 is thinner, the heat transfer resistance is small, and the heat transfer property is excellent. Heat exchange will be performed efficiently.

〔発明の効果〕〔Effect of the invention〕

以上の通り、この発明は、容器本体の外部で流路壁を組
み立てた後、この流路壁を容器本体内部に挿入し内面に
密着させて固定するから、容器本体内での作業は大幅に
少なくなると共に、流路壁の表面を平滑で溶接部等が露
出しない内板で構成するから、はとんど仕上げを要せず
、仕上げ作業を行う場合でも通常の槽容器と同様に行え
ると共に、メンテナンスの手間が大幅に少なくなる。ま
た、熱媒又は冷媒の流路は容器本体の胴部及び胴部より
肉厚の大きい底部鏡面板部の内面にも設けられているの
で、使用時、内板を通しての熱媒又は冷媒との熱交換効
率が良く、かつ、内仮に対する処理液の付着も少ない。As described above, in this invention, after assembling the channel wall outside the container body, this channel wall is inserted into the container body and fixed tightly against the inner surface, so the work inside the container body is greatly reduced. In addition, because the surface of the channel wall is smooth and the inner plate is constructed with no exposed welded parts, there is little need for finishing. , maintenance effort is significantly reduced. In addition, the flow path for the heat medium or refrigerant is also provided on the inner surface of the body of the container body and the bottom mirror plate, which is thicker than the body. Heat exchange efficiency is good, and there is little adhesion of processing liquid to the inner layer.

従って、従来に比べて容器製作の能率向上が図れ、メン
テナンスも容易になると共に、運転効率及び製品品質の
向上を図り得る。Therefore, compared to the conventional method, the efficiency of container manufacturing can be improved, maintenance can be made easier, and operating efficiency and product quality can be improved.

【図面の簡単な説明】[Brief explanation of drawings]

第１図はこの発明の一実施例を示す縦断面図、第２図は
第１図の要部拡大図、第３図はこの発明の他の実施例を
示す縦断面図、第４図、第５図、第６図、第７図は従来
例を示す縦断面図である。 ｌ・・・・・・容器本体、２・・・・・・円筒形胴部、
３．４・・・・・・皿形鏡面板、５Ａ、５Ｂ・・・・・
・流路壁、６・・・・・・内板、７・・・・・・仕切板
、８・・・・・・外ストリップ、９．９い９□・・・・
・・流路、 １０．１０．．１０□・・・・・・入口、１１．１１１
．１１□・・・・・・出口、１２・・・・・・槽容器ノ
ズル、 ３・・・・・・閉塞板、 ■ ４・・・・・・切欠部。 Ａ 第 図 第 図 第 図 第 図 第 図FIG. 1 is a longitudinal sectional view showing one embodiment of the present invention, FIG. 2 is an enlarged view of the main part of FIG. 1, FIG. 3 is a longitudinal sectional view showing another embodiment of the invention, FIG. FIG. 5, FIG. 6, and FIG. 7 are vertical sectional views showing conventional examples. l... Container body, 2... Cylindrical body,
3.4...Dish-shaped mirror plate, 5A, 5B...
・Channel wall, 6... Inner plate, 7... Partition plate, 8... Outer strip, 9.9 9□...
...Flow path, 10.10. ．． 10□・・・・Entrance, 11.111
．． 11□...Outlet, 12...Tank container nozzle, 3...Closing plate, ■4...Notch. A

Claims (3)

【特許請求の範囲】[Claims] （１）、内板の裏面と直角に仕切板を間隔をおいて並設
し、仕切板の先端間に外ストリップを跨設し、前記内板
と外ストリップとの間に仕切板により仕切られた熱媒又
は冷媒の流路を有する流路壁を形成し、この流路壁を外
ストリップにて容器本体内面に密着させて固定したこと
を特徴とする槽容器。(1) Partition plates are arranged in parallel at intervals at right angles to the back surface of the inner plate, an outer strip is provided between the tips of the partition plates, and the inner plate and the outer strip are separated by the partition plate. 1. A tank container characterized in that a flow path wall having a flow path for a heating medium or a coolant is formed, and the flow path wall is fixed in close contact with the inner surface of the container body by an outer strip. （２）、熱媒又は冷媒の流路を有する流路壁を螺旋状と
し、容器本体の胴部及び底部鏡面板部の内面に密着させ
て固定したことを特徴とする請求項（１）記載の槽容器
。(2) Claim (1) characterized in that the channel wall having the heat medium or coolant channel is formed into a spiral shape and is fixed in close contact with the inner surface of the body portion and the bottom mirror plate portion of the container body. tank container. （３）、容器本体の底部鏡面板部に熱媒又は冷媒の流路
を有する螺旋状流路壁を内面に密着させて設け、該底部
鏡面板部に連なる容器本体の胴部に熱媒又は冷媒の流路
を有する周方向に蛇行した流路壁を内面に密着させて設
けたことを特徴とする請求項（１）記載の槽容器。(3) A spiral flow path wall having a heat medium or coolant flow path is provided in the bottom mirror plate of the container body in close contact with the inner surface, and the body of the container body connected to the bottom mirror plate is provided with a heat medium or a coolant. 2. The tank container according to claim 1, wherein a circumferentially meandering channel wall having a coolant channel is provided in close contact with the inner surface.